Professor Walkiria Schlindwein

Job: Professor of Pharmaceutics

Faculty: Health and Life Sciences

School/department: Leicester School of Pharmacy

Research group(s): Pharmaceutical Technologies

Address: 蜜桃直播, The Gateway, Leicester, LE1 9BH.

T: +44 (0)116 257 7124

E: wss@dmu.ac.uk

W: /pharmacy

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Personal profile

Prof Schlindwein graduated as Chemical Engineer in 1984 from the Federal University of Rio de Janeiro, UFRJ, Brazil. She obtained her M.Sc. in Polymer Science and Technology from the Institute of Macromolecules of the UFRJ, Brazil in 1986, PhD in Chemistry from the Department of Chemistry of the University of Leicester, England, in 1990, and DSc in Chemistry from the UFRJ in 1992.

She has over 25 years of experience in academia and is currently Professor of Pharmaceutics at the Leicester School of Pharmacy, 蜜桃直播 (蜜桃直播). She has led the creation of the first MSc in Pharmaceutical Quality by Design (QbD) that has attracted national and international students since 2012. In the UK, education provision in the QbD area has been largely dominated by this programme. She has established a high-profile curriculum in this domain, through engagement with a number of multinational companies, including Astra Zeneca and GlaxoSmithKline, technology providers and the UK regulatory agency, MHRA. She has chaired several events and workshops to support and publicise the research and teaching excellence in pharmaceutical product development and manufacture. Her expertise is in the areas of polymer science and technology, advanced techniques for materials’ characterisation, pharmaceutical Quality by Design, and extrusion processes for early phase product development using in-line analytical tools

Research group affiliations

Leicester Institute for Pharmaceutical Health and Social Care Innovations

Publications and outputs

dc.title: Enhancing Process Control and Quality in Amorphous Solid Dispersions Using In-Line UV鈥揤is Monitoring of L* as a Real-Time Response dc.contributor.author: Bezerra, Mariana; Almeida, Juan; de Castro, Matheus; Grootveld, Martin; Schlindwein, W. S. dc.description.abstract: Background: This study demonstrates the application of the sequential design of experiments (DoE) approach within the quality by design (QbD) framework to optimize extrusion processes through screening, optimization, and robustness testing. Methods: An in-line UV鈥揤is process analytical technology (PAT) system was successfully employed to monitor critical quality attributes (CQAs) of piroxicam amorphous solid dispersion (ASD) extrusion products, specifically lightness (L*). Results: L* measurement proved highly effective for ensuring the quality and uniformity of ASDs, offering real-time insights into their physical appearance and process stability. Small variations in L* acted as early indicators of processing issues, such as phase separation or bubble formation, enabling timely intervention. This straightforward and rapid technique supports real-time process monitoring and control, allowing automated adjustments to maintain product consistency and quality. By adopting this strategy, manufacturers can minimize variability, reduce waste, and ensure adherence to quality target product profiles (QTPPs). Conclusions: Overall, this study highlights the value of in-line UV鈥揤is spectroscopy as a PAT tool in hot melt extrusion, enhancing CQA assessment and advancing the efficiency and reliability of ASD manufacturing. dc.description: open access article
dc.title: Optimizing extrusion processes and understanding conformational changes in itraconazole amorphous solid dispersions using in-line UV鈥揤is spectroscopy and QbD principles dc.contributor.author: Triboandas, Hetvi; Bezerra, M.; Almeida, J.; De Castro, M.; Santos, B.; Schlindwein, W. S. dc.description.abstract: This paper presents a comprehensive investigation of the manufacturing of itraconazole (ITZ) amorphous solid dispersions (ASDs) with Kolllidon庐 VA64 (KVA64) using hot-melt extrusion (HME) and in-line process monitoring, employing a Quality by Design (QbD) approach. A sequential Design of Experiments (DoE) strategy was utilized to optimize the manufacturing process, with in-line UV鈥揤is spectroscopy providing real-time monitoring. The first DoE used a fractional factorial screening design to evaluate critical process parameters (CPPs), revealing that ITZ concentration had the most significant impact on the product quality attributes. The second DoE, employing a central composite design, explored the interactions between feed rate and screw speed, using torque and absorbance at 370 nm as responses to develop a design space. Validation studies confirmed process robustness across multiple days, with stable in-line UV鈥揤is spectra and consistent product quality using 30 % ITZ, 300 rpm, 150 掳C and 7 g/min as the optimized process conditions. Theoretical and experimental analyses indicated that shifts in UV鈥揤is spectra at different ITZ concentrations were due to conformational changes in ITZ, which were confirmed through density functional theory (DFT) calculations and infrared spectroscopy. This work offers novel insights into the production and monitoring of ITZ-KVA64-ASDs, demonstrating that in-line UV鈥揤is spectroscopy is a powerful tool for real-time process monitoring and/or control. dc.description: open access article
dc.title: Itraconazole Amorphous Solid Dispersion Tablets: Formulation and Compaction Process Optimization Using Quality by Design Principles and Tools dc.contributor.author: Triboandas, Hetvi; Pitt, Kendal; Bezerra, Mariana; Ach-Hubert, Delphine; Schlindwein, W. S. dc.description.abstract: BCS Class II drugs, such as itraconazole (ITZ), exhibit poor solubility (1鈥�4 ng/mL) and so require solubility enhancement. Therefore, ITZ and Kollidon庐 VA64 (KOL) amorphous solid dispersions (ASDs) were produced using hot-melt extrusion (HME) to improve ITZ鈥檚 poor solubility. A novel strategy for tablet formulations using five inorganic salts was investigated (KCl, NaCl, KBr, KHCO3 and KH2PO4 ). These kosmotopric salts are thought to compete for water hydration near the polymer chain, hence, preventing polymer gelation and, therefore, facilitating disintegration and dissolution. Out of all the formulations, the KCl containing one demonstrated acceptable tensile strength (above 1.7 MPa), whilst providing a quick disintegration time (less than 15 min) and so was selected for further formulation development through a design of the experiment approach. Seven ITZ-KOL-ASD formulations with KCl were compacted using round and oblong punches. Round tablets were found to disintegrate under 20 min, whereas oblong tablets disintegrated within 10 min. The round tablets achieved over 80% ITZ release within 15 min, with six out of seven formulations achieving 100% ITZ release by 30 min. It was found that tablets comprising high levels of Avicel庐 pH 102 (30%) and low levels of KCl (5%) tend to fail the disintegration target due to the strong bonding capacity of Avicel庐 pH 102. The disintegration time and tensile strength responses were modeled to obtain design spaces (DSs) relevant to both round and oblong tablets. Within the DS, several formulations can be chosen, which meet the Quality Target Product Profile (QTPP) requirements for immediate-release round and oblong tablets and allow for flexibility to compact in different tablet shape to accommodate patients鈥� needs. It was concluded that the use of inorganic salts, such as KCl, is the key to producing tablets of ITZ ASDs with fast disintegration and enhanced dissolution. Overall, ITZ-KOL-ASD tablet formulations, which meet the QTPP, were achieved in this study with the aid of Quality by Design (QbD) principles for formulation and compaction process development and optimization. dc.description: open access article
dc.title: Development and Validation of an In鈥怢ine API Quantification Method Using AQbD Principles Based on UV鈥怴is Spectroscopy to Monitor and Optimise Continuous Hot Melt Extrusion Process dc.contributor.author: Almeida, Juan; Bezerra, Mariana; Markl, Daniel; Berghaus, Andreas; Borman, Phil; Schlindwein, W. S. dc.description.abstract: A key principle of developing a new medicine is that quality should be built in, with a thorough understanding of the product and the manufacturing process supported by appropriate process controls. Quality by design principles that have been established for the development of drug products/substances can equally be applied to the development of analytical procedures. This paper presents the development and validation of a quantitative method to predict the concentration of piroxicam in Kollidon庐 VA 64 during hot melt extrusion using analytical quality by design principles. An analytical target profile was established for the piroxicam content and a novel in鈥恖ine analytical procedure was developed using predictive models based on UV鈥怴is absorbance spectra collected during hot melt extrusion. Risks that impact the ability of the analytical procedure to measure piroxicam consistently were assessed using failure mode and effect analysis. The critical analytical attributes measured were colour (L* lightness, b* yellow to blue colour parameters鈥攊n鈥恜rocess critical quality attributes) that are linked to the ability to measure the API content and transmittance. The method validation was based on the accuracy profile strategy and ICH Q2(R1) validation criteria. The accuracy profile obtained with two validation sets showed that the 95% 尾鈥恊xpectation tolerance limits for all piroxicam concentration levels analysed were within the combined trueness and precision acceptance limits set at 卤5%. The method robustness was tested by evaluating the effects of screw speed (150鈥�250 rpm) and feed rate (5鈥�9 g/min) on piroxicam content around 15% w/w. In鈥恖ine UV鈥怴is spectroscopy was shown to be a robust and practical PAT tool for monitoring the piroxicam content, a critical quality attribute in a pharmaceutical HME process. dc.description: open access journal
dc.title: Modelling the Effect of Process Parameters on the Wet Extrusion and Spheronisation of High-Loaded Nicotinamide Pellets Using a Quality by Design Approach dc.contributor.author: Theismann, Eva-Maria; Keppler, Julia K; Owen, Martin; Schwarz, Karin; Schlindwein, W. S. dc.description.abstract: The aim of the present study was to develop an alternative process to spray granulation in order to prepare high loaded spherical nicotinamide (NAM) pellets by wet extrusion and spheronisation. Therefore, a quality by design approach was implemented to model the effect of the process parameters of the extrusion-spheronisation process on the roundness, roughness and useable yield of the obtained pellets. The obtained results were compared to spray granulated NAM particles regarding their characteristics and their release profile in vitro after the application of an ileocolon targeted shellac coating. The wet extrusion-spheronisation process was able to form highly loaded NAM pellets (80%) with a spherical shape and a high useable yield of about 90%. However, the water content range was rather narrow between 24.7% and 21.3%. The design of experiments (DoE), showed that the spheronisation conditions speed, time and load had a greater impact on the quality attributes of the pellets than the extrusion conditions screw design, screw speed and solid feed rate (hopper speed). The best results were obtained using a low load (15 g) combined with a high rotation speed (900 m/min) and a low time (3鈥�3.5 min). In comparison to spray granulated NAM pellets, the extruded NAM pellets resulted in a higher roughness and a higher useable yield (63% vs. 92%). Finally, the coating and dissolution test showed that the extruded and spheronised pellets are also suitable for a protective coating with an ileocolonic release profile. Due to its lower specific surface area, the required shellac concentration could be reduced while maintaining the release profile dc.description: Open access article
dc.title: Pharmaceutical excipients properties and screw feeder performance in continuous processing lines: a Quality by Design (QbD) approach dc.contributor.author: Santos, B.; Carmo, F.; Schlindwein, W. S.; Muirhead, G.; Rodriguez, C.; Cabral, L.; Westrup, J.; Pitt, K. dc.description.abstract: Screw feeder performance is a critical aspect in continuous manufacturing processes. Pharmaceutical excipients, such as mannitol, microcrystalline cellulose, lactose monohydrate, and anhydrous dibasic calcium phosphate can present problems in ensuring a continuous stable feed rate due to their sub-optimal flow properties. In alignment with Quality by Design (QbD) goals, the aim of this work was to identify and explain critical sources of variability of some powder excipients delivery by screw feeding, in particular to continuous processing lines. Pharmaceutical excipients with a wide range of material properties were selected, and the impact of their flow and density properties on screw feeder performance was investigated. The analysis of the powder conveying by the screws was performed at different hopper fills and different screw speeds. A multivariable model involving bulk density (CBD) and parameters from FT4 dynamic downwards testing (SI) and dynamic upwards testing (SE) explained 95.7% of excipients feed rates (p<.001). The study gathers valuable information about the screw feeder performance and input materials properties that can help process understanding and QbD-based development of solid dosage forms in continuous processing lines. dc.description: The file attached to this record is the author's final peer reviewed version. The Publisher's final version can be found by following the DOI link.
dc.title: In-Line UV-Vis Spectroscopy as a Fast-Working Process Analytical Technology (PAT) during Early Phase Product Development Using Hot Melt Extrusion (HME) dc.contributor.author: Schlindwein, W. S.; Bezerra, M.; Almeida, J.; Berghaus, A; Owen, M.; Muirhead, G. dc.description.abstract: This paper displays the potential of an in-line PAT system for early phase product development during pharmaceutical continuous manufacturing following a Quality by Design (QbD) framework. Hot melt extrusion (HME) is used as continuous manufacturing process and UV鈥� Vis spectroscopy as an in-line monitoring system. A sequential design of experiments (DoE) (screening, optimisation and verification) was used to gain process understanding for the manufacture of piroxicam (PRX)/Kollidon庐 VA64 amorphous solid dispersions. The influence of die temperature, screw speed, solid feed rate and PRX concentration on the critical quality attributes (CQAs) absorbance and lightness of color (L*) of the extrudates was investigated using multivariate tools. Statistical analysis results show interaction effects between concentration and temperature on absorbance and L* values. Solid feed rate has a significant effect on absorbance only and screw speed showed least impact on both responses for the screening design. The optimum HME process conditions were confirmed by 4 independent studies to be 20% w/w of PRX, temperature 140 掳C, screw speed 200 rpm and feed rate 6 g/min. The in-line UV-Vis system was used to assess the solubility of PRX in Kollidon庐 VA64 by measuring absorbance and L* values from 230 to 700 nm. Oversaturation was observed for PRX concentrations higher than 20% w/w. Oversaturation can be readily identified as it causes scattering in the visible range. This is observed by a shift of the baseline in the visible part of the spectrum. Extrudate samples were analyzed for degradation using off-line High-Performance Liquid Chromatography (HPLC) standard methods. Results from off-line experiments using differential scanning calorimetry (DSC), and X-ray diffraction (XRD) are also presented. dc.description: open access article
dc.title: Pharmaceutical quality by design: a practical approach. dc.contributor.author: Schlindwein, W. S.; Gibson, Mark
dc.title: EPR and XANES studies of anaerobic photolysis of iso-propilpyridinecobaloxime: Elucidation of the reactivity of the Co(II) primary product dc.contributor.author: Rangel, M.; Leite, A.; Silva, A.; De Castro, B.; Schlindwein, W. S.; Murphy, L. dc.description.abstract: Anaerobic photolysis of iso-propilpyridinecobaloxime was monitored by EPR and X-ray Absorption Near Edge spectroscopy (XANES). The spectra of the cobalt(II) photolysis products were analyzed and compared with those obtained for parent cobalt(II) dimethylglyoximato complexes in order to rationalize the involvement of photolysis primary products in further reactions in solution. The results obtained upon photolysis in frozen matrix, confirm that the photolysis primary product is the five coordinate cobalt(II) complex, [Co(DH)2py], and that this species is only observable in frozen solution. As the matrix is relaxed to room temperature the five coordinate species evolves to give rise to a six coordinate cobalt(II) complex, [Co(DH)2py2], that persists at room temperature and that is observable in EPR upon re-cooling to frozen solution. When monitoring the warming up of the irradiated frozen solution we observe an EPR signal which is assigned to a square planar species, [Co(DH)2], providing evidence for the source of pyridine molecules to originate the compound with two bound pyridine molecules. Since the latter signal is lost upon warming we hypothesize that the four coordinate species polymerizes or packs into diamagnetic forms at room temperature. The supposition is corroborated by comparison of the values of the magnetic moments of compounds [Co(DH)2py2], [Co(DH)2py] and [Co(DH)2] as powders and in solution. EPR titration of compound [Co(DH)2] with pyridine substantiates the latter results and shows that the complex with two bound pyridine molecules is the predominant species from a 1:1 M ratio. The XANES profiles of powder and solution samples of compound [Co(DH)2] are meaningfully different and indicative that substantial axial interactions are present in solution while the powder鈥檚 profile is closely related with those described for square planar complexes. The presence of two solvent molecules bound to [Co(DH)2] in solution is confirmed by the values of the spin-Hamiltonian parameters obtained for the same sample. The use of XANES spectroscopy was particularly valuable to provide independent evidence that the structure of [Co(DH)2] and [Co(DH)2py] is different in powder and in solution and to monitor the change in oxidation state and geometry during the progression of the photolysis process.
dc.title: Using the Box-Behnken experimental design to optimise operating parameters in pulsed spray fluidised bed granulation dc.contributor.author: Liu, H.; Wang, K.; Schlindwein, W. S.; Li, M. dc.description.abstract: In this work, the influence factors of pulsed frequency, binder spray rate and atomisation pressure of a top-spray fluidised bed granulation process were studied using the Box鈥揃ehnken experimental design method. Different mathematical models were developed to predict the mean size of granules, yield, relative width of granule distribution, Hausner ratio and final granule moisture content. The study has supported the theory that the granule size can be controlled through the liquid feed pulsing. However, care has to be taken when the pulsed frequency is chosen for controlling the granule size due to the nonlinear quadratic relation in the regression model. The design space of the ranges of operating parameters has been determined based on constraints of the mean size of granules and granule yield. High degree of prediction obtained from validation experiments has shown the reliability and effectiveness of using the Box鈥揃ehnken experimental design method to study a fluidised bed granulation process.

Key research outputs

Research interests/expertise

Her current research focuses on material sciences, especially polymers used in pharmaceutical applications. She supervises PhD students on projects related to improving the formulation of poorly soluble drugs and conducting studies using various methods for amorphisation of crystalline drug actives like hot melt extrusion. She has extensive knowledge in Pharmaceutical Quality by Design practices applied to product development and manufacture.

Areas of teaching

Quality by Design Principles and Tools
Pharmaceutical Materials Sciences
Process Analytical Technology
Hot Melt ExtrusionPharmaceutical Product Development and Manufacture

Qualifications

PhD, MSc, ChemEng

蜜桃直播 taught

BSc Pharmaceutical and Cosmetic Science,

Full time MSc Pharmaceutical Quality by Design,

Distance learning in MSc Quality by Design for the Pharmaceutical Industry

Honours and awards

Membership of external committees

Member of the CMAC Advisory Board at University of Strathclyde

Membership of professional associations and societies

Member of the Academy of Pharmaceutical Sciences and Regulatory Focus Group

Member of the International Society of Pharmaceutical Engineering and Modelling Focus Group

Projects

Contimuous manufacture of amorphous dispersions of porrly soluble drugs (2017 to date)

In-line process analytical technology for process monitoring (2028 to date)

Amorphous solid dispersion solubility predictions (2020 to date)

Forthcoming events

Tabletting School 2025 meeting at Leicester, 17-18th June 2025

A Hands-On Approach to Mastering Tablet Production

Conference attendance

Bezerra, M.; Muirhead, G.; Berghaus, A.; Schlindwein, W., Enabling Rapid Product Development with in-line UV-Vis Spectroscopy as PAT tool for Hot Melt Extrusion: A case study, The Ninth pan-European Conference on PAT and QbD Sciences, EuFEPS, Manchester, May 2018

Almeida, J.; Bezerra, M.; Berghaus, A.; Markl, D.; Zeitler, A.; Muirhead, G., and Schlindwein, W., Building Predictive Models for in-line UV-Vis Spectroscopy to Monitor Continuous Pharmaceutical Hot Melt Extrusion Processes, 3rd International Symposium on Continuous Manufacturing Processes, London October 2018.

Triboandas, H.; Schlindwein, W., Continuous manufacture and monitoring of itraconazole amorphous solid dispersions by hot melt extrusion using in-line UV-Vis spectroscopy, UkPharm Sci, APS meeting, Greenwich, 11-13 Sep 2019.

Bezerra, M., Almeida, J., Triboandas, H., Berghaus, A., Parekh, R., Whitaker, D., Mack, J, and Schlindwein, W., HME process optimisation with in-line UV-Vis spectroscopy and machine learning algorithm, PBP world meeting, Austria, 23-26 March 2020.

Bezerra, M., Almeida, J., de Castro, M., Grootveld, M., and Schlindwein, W. Hot-Melt extrusion monitoring through In-line UV-Vis spectroscopy: challenging the framework using QbD, APS Annual Conference, Huddersfield, Sep 2024.

de Castro, M, Smith, S., Khurana, J., Cordeiro, S. and Schlindwein, W., New Insights into Ibuprofen Polymorph Interconversion: Addressing Unresolved Dynamics, APS Annual Conference, Huddersfield, Sep 2024.

Recent research outputs

Almeida, J., Bezerra, M., Markl, D., Berghaus, A., Borman, P. and Schlindwein, W., Development and Validation of an in-line API Quantification Method using AQbD Principles based on UV-Vis Spectroscopy to Monitor and Optimise Continuous Hot Melt Extrusion Process, Pharmaceutics, 12(2), 150 (2020) .
Triboandas, Hetvi; Pitt, Kendal; Bezerra, Mariana; Ach-Hubert, Delphine; Schlindwein, Walkiria, (2022), Itraconazole Amorphous Solid Dispersion Tablets: Formulation and Compaction Process Optimization Using Quality by Design Principles and Tools, Pharmaceutics, 14(11) 2398,
Triboandas, H., Bezerra, M., Almeida, J., de Castro, M., Santos, B.A.M.C. and Schlindwein, W. (2024) Optimizing extrusion processes and understanding conformational changes in itraconazole amorphous solid dispersions using in-line UV–Vis spectroscopy and QbD principles. International Journal of Pharmaceutics: X, 8, pp. 100308.
Bezerra, M.; Almeida, J.; de Castro, M.; Grootveld, M.; Schlindwein,W. Enhancing Process Control and Quality in Amorphous Solid Dispersions Using In-Line UV–Vis Monitoring of L* as a Real-Time Response. Pharmaceutics (2025), 17, 151. .

Key articles information

The development of amorphous solid dispersions (ASDs) via hot melt extrusion (HME) has made significant progress and is increasingly recognized as a valuable technique inpharmaceutical formulation. ASDs improve the solubility and bioavailability ofpoorly water-soluble drugs by transforming them into an amorphous state, which is generallymore soluble than their crystalline counterparts. HME is especially useful inthis area because it efficiently disperses active pharmaceutical ingredients (APIs) withina polymer matrix through the application of heat and mechanical shear. Its versatility allows for continuous processing, the creation of various dosage forms (like films,tablets, and granules), solvent free process, and enhanced scalability.

Over the past two decades, regulatory authorities have collaborated with industry toadvance changes in the quality paradigm, aiming to understand pharmaceutical processesand product quality more comprehensively. This new approach, often referred to as the’enhanced’ approach or pharmaceutical quality by design (QbD), encourages innovation across the pharmaceutical lifecycle.

The research carried out in the last 5 years show the potential of QbD approaches using continuous extrusion to advance the field of process analytical technology by offering a robust, real-time solution for ensuring product quality and optimizing manufacturing processes.

Consultancy work

Product Development – company RB (2022)

The project aimed to create solid dispersions in the form of powders and pellets using the hot melt extrusion method. It involved six different workstreams, each focused on a different active ingredient.

In-line PAT for cleaning validation – company Kindeva (2022/23)

The project aimed to investigate the feasibility of UV-Vis spectrophotometry in transmission configuration for the process control of pharmaceutical cleaning, batching and manufacturing.

Fast screening methods to develop amorphous drug products via hot melt extrusion – company RB (2021/22)

The project focused on developing methods for formulation optimisation and scall up manufacturing methods.

Current research students

Matheus de Castro – PhD student, 1^st supervisor (2024/27)
Chuhong Cheng – PhD student, 2^nd supervisor (2024/27)

Externally funded research grants information

Industry funded project: Smart manufacturing platform for innovative oral delivery of amorphous drug substances (£120 k, PI – 2024/27)

This PhD project focuses on creating a new type of ibuprofen tablet that dissolves quickly in your mouth. The main goal is to explore how using a special form of ibuprofen (called "amorphous") can help solve problems with current medicines. This could lead to better manufacturing processes (like easier handling of the powder) and improved results for patients, such as better absorption of the drug and a better taste.

EPSRC grant: Mechanistic Multiscale Modelling of Drug Release from Immediate Release Tablets (£1.1 M, Co-I – 2024/27)

This is an EPSRC project lead by 蜜桃直播 in collaboration with University of Surrey. The aim of the project is to develop first principles model to predict drug release profile from an IR tablet.

Innovate UK grant: A Regulatory Science Network for the Digital Transformation of Medicines Development and Manufacturing (£1 M CoI – 2024/25)

The proposed project aims to generate research and insights to help modernize the way medicines are developed and made in the pharmaceutical industry. It focuses on using data science, including artificial intelligence (AI) and predictive models, to improve the processes of creating and manufacturing medicines, especially in the health and life sciences fields. This project is in collaboration with University of Strathclyde, and CCDC Cambridge.

Published patents

Novel Composition 2022 - International Publication number W O 2022/185073 Al

This invention is directed to a novel pharmaceutically active ingredient-containing composition. In particular, the present invention is directed to an NSAID-containing 5 composition in which the NSAID is in an amorphous form.

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